DE102011107229B4 - Heating system for a vehicle and vehicle with a heating system - Google Patents

Abstract

Heating system for a vehicle (10), comprising: - a DC-DC converter (2) for converting a high-voltage DC voltage of a high-voltage network (11) of the vehicle (10) into a low-voltage DC voltage of a low-voltage network (12) of the vehicle (10), - a heating element (1) , which can be operated with the low-voltage direct voltage, - the heating system (20) also comprising a low-voltage energy storage (3) coupled to the heating element (1) for providing the low-voltage direct voltage, characterized in that the heating system (20) also has control means (7) comprises, wherein the control means (7) are designed to set a target output voltage of the DC-DC converter (2) lower than 1.05 times the rest voltage of the low-voltage energy storage (3), so that the energy provided by the DC-DC converter (2) as low-voltage DC voltage is not used for charging the low-voltage energy storage device (3) is used.

Description

The present invention relates to a heating system for a vehicle, in particular a hybrid vehicle or an electric vehicle, and a corresponding vehicle with this heating system.

The DE 94 13 500 U1 discloses an electrical heating element that can be connected to a traction battery.

The GB 2 443 225 A describes a heater that includes a heating element that can be operated at a high DC voltage and a control element that can be operated at a low DC voltage.

From the DE 10 2005 022 204 A1 is known a method for heating a battery in a vehicle with a battery heater, comprising the steps of: determining a key-off condition, and allowing energy to flow from the battery to the heater after determining the key-off condition.

In the DE 10 2007 001 673 A1 An on-board electrical system system for a motor vehicle is disclosed, which comprises a high-voltage energy storage device for providing a high-voltage voltage network for the voltage supply of one or more high-voltage consumers and a first converter device for converting the high-voltage of the high-voltage voltage network to a predetermined low-voltage voltage of a low-voltage voltage network for the power supply to one or more low-voltage consumers. Furthermore, the on-board electrical system system comprises a second converter device, which is connected in parallel to the first converter device, and via which a predetermined energy input into the low-voltage network takes place at least temporarily.

Although heating elements are known which are supplied by a high-voltage direct voltage (see above), the use of heating elements which are supplied by a low-voltage direct voltage (for example 12 V), in particular for an auxiliary heater of a vehicle, is widespread. The maximum operating time of such an auxiliary heater for normal use, in which the vehicle's engine is not running, depends on the energy storage capacity of a corresponding low-voltage energy storage device (e.g. a 12 V battery) in the vehicle. The lower the capacity of this low-voltage energy storage system, the shorter the possible operating time of the auxiliary heater.

The present invention therefore sets itself the task of extending the maximum operating time of such an auxiliary heater regardless of the capacity of the low-voltage energy storage unit supplying this auxiliary heater.

According to the invention, this object is achieved by a heating system for a vehicle according to claim 1 and by a vehicle according to claim 5. The dependent claims define preferred and advantageous embodiments of the present invention.

Within the scope of the present invention, a heating system for a vehicle is provided. This heating system includes a DC-DC converter and a heating element. The DC-DC converter converts a high-voltage DC voltage from a high-voltage network of the vehicle into a low-voltage DC voltage from a low-voltage network of the vehicle. The heating element can be operated with low-voltage direct voltage.

The low-voltage DC voltage of the low-voltage network is, for example, 12 V for a car and 24 V for a truck, while the high-voltage DC voltage of the vehicle's high-voltage network is 100 V to 800 V (e.g. 360 V). The low-voltage network supplies consumers of the vehicle, such as the on-board computer, the radio, the air conditioning, while the high-voltage network supplies voltage, in particular, to an electric motor for driving the vehicle.

By the DC-DC converter converting the high-voltage DC voltage into the low-voltage DC voltage, the heating element can advantageously also be supplied with energy, which is provided by a device that provides its energy in the form of a high-voltage DC voltage, as is the case, for example, with a high-voltage energy storage device. This allows the maximum operating time of the heating system to be extended without the capacity of the vehicle's low-voltage energy storage having to be increased or another low-voltage energy storage being required as a reserve to supply the heating element.

The heating system can also include a rectifier to convert a provided alternating voltage into the high-voltage direct voltage.

With the help of the rectifier, the heating system can be supplied via a corresponding external AC voltage network (for example an AC voltage network in a house).

In addition, the heating system includes a low-voltage energy storage device, which is coupled to the heating element in order to supply it with the low-voltage direct voltage for energy supply This low-voltage energy storage device can be, for example, the vehicle's 12 V battery.

Furthermore, the heating system can include a high-voltage energy storage device, which is coupled to the DC-DC converter, so that the energy provided by the high-voltage energy storage device can be used to supply energy to the heating element. This high-voltage energy storage can, for example, be the high-voltage energy storage of the vehicle with which an electric motor of the vehicle is supplied with energy to drive the vehicle.

If, for example, the heating system is connected to an external AC voltage network via its rectifier, the heating element can advantageously be supplied via the external AC voltage network and the high-voltage energy storage can be charged during periods in which the electricity price is low, while in other periods the heating system can be charged via the high-voltage energy storage and also via the low-voltage energy storage is supplied.

Furthermore, the heating system also includes control means which are designed such that the control means set a target output voltage of the DC-DC converter depending on a rest voltage of the low-voltage energy storage such that the target output voltage is in the range of the rest voltage, so that the energy provided by the DC-DC converter as low-voltage DC voltage is not used Charging the low-voltage energy storage is used.

The resting voltage of the low-voltage energy storage device is understood to mean the voltage which is established at the low-voltage energy storage device depending on the state of charge of the low-voltage energy storage device when the low-voltage energy storage device does not supply any consumer with energy and is not being charged. If the target output voltage of the DC-DC converter is lower than 1.05 times the rest voltage or, better, lower than the rest voltage, the low-voltage energy storage is not charged by the energy provided via the DC-DC converter, so that advantageously no further energy losses occur here. In other words, in this embodiment it is ensured that the energy provided via the DC-DC converter only supplies energy to elements of the heating system on the low-voltage side, such as the heating element (which may include a fan for distributing heated air) and the control means. Thanks to this corresponding control strategy of the DC-DC converter, the heating system according to the invention can also be used in high-voltage energy storage devices with a small capacity that are designed for performance.

In a further embodiment according to the invention, the heating system comprises further control means in order to control the high-voltage energy storage device. These further control means are designed in such a way that when managing the amount of energy stored in the high-voltage energy storage, they take into account a supply to the heating element, for example by adapting the high-voltage energy management in such a way that a corresponding power reserve for the heating element on the high-voltage side is taken into account or realized.

Within the scope of the present invention, a vehicle is also provided which comprises a high-voltage network, a low-voltage network, an electric motor for driving the vehicle and a heating system according to the invention. The DC-DC converter of the heating system is coupled to the high-voltage network and the low-voltage network of the vehicle while the heating element of the heating system is coupled to the low-voltage network of the vehicle.

The present invention is particularly suitable for hybrid vehicles and electric vehicles, in which the heating system according to the invention can also be supplied with energy from the high-voltage energy storage. Of course, the present invention is not limited to this preferred area of application, since the present invention can in principle also be used on ships, aircraft and track-bound or track-guided vehicles.

• 1 stellt schematisch ein erfindungsgemäßes Heizsystem dar, welches mit einem externen Wechselspannungsnetz gekoppelt ist.
• In 2 ist ein erfindungsgemäßes Fahrzeug dargestellt, welches ein erfindungsgemäßes Heizsystem umfasst.

The present invention is described in detail below using embodiments of the invention with reference to the figures.

• 1 schematically represents a heating system according to the invention, which is coupled to an external AC voltage network.
• In 2 A vehicle according to the invention is shown, which includes a heating system according to the invention.

In 1 a heating system 20 according to the invention is shown schematically. The heating system 20 includes a heating element 1, a DC-DC converter 2, a 12 V battery 3, a high-voltage battery 4, a rectifier 5, a controller 7 for controlling the DC-DC converter 2 and a controller 8 for controlling the high-voltage battery 4. The 12 V battery 3 supplies a low-voltage network 12 of a vehicle 10 (see 2 ) with energy, with a fan 6 of the heating system 20, the heating element ment 1 and the controller 7 are connected to this low-voltage network 12 as consumers. The DC-DC converter 2, which is connected on the output side to the low-voltage network 12 and on the input side to a high-voltage network 11 of the vehicle 10, provides the low-voltage network 12 with energy in the form of a DC voltage (in the range of 12 V), provided that it has a corresponding high-voltage voltage (in the range of 360 V) is provided either by the high-voltage battery 4 or via the rectifier 5, which is coupled to an external AC voltage network.

The controller 7 detects a rest voltage of the 12 V battery 3 and sets the (target) output voltage of the DC-DC converter 2 to this rest voltage in order to prevent the energy made available via the DC-DC converter 2 from being used to charge the 12 V battery 3 used. When managing the energy for the high-voltage battery 4, the controller 8 takes into account that not all of the energy stored in the high-voltage battery 4 is used to supply an electric motor 9 (see 2 ) of the vehicle 10 is used, but also that a predetermined amount of energy is available to supply the heating element 1.

2 schematically represents the vehicle 10 according to the invention, which includes the heating system 20 according to the invention. At the in 2 In the embodiment shown, the heating system 20 includes an auxiliary heater 1 or a heating element, a DC-DC converter 2, a low-voltage energy storage 3 and a high-voltage energy storage 4, which is coupled to both the DC-DC converter 2 and the electric motor 9 of the vehicle 10.

Claims (5)

Heating system for a vehicle (10), comprising: - a DC-DC converter (2) for converting a high-voltage DC voltage of a high-voltage network (11) of the vehicle (10) into a low-voltage DC voltage of a low-voltage network (12) of the vehicle (10), - a heating element (1) , which can be operated with the low-voltage direct voltage, - the heating system (20) also comprising a low-voltage energy storage device (3) coupled to the heating element (1) for providing the low-voltage direct voltage, characterized in that the heating system (20) also includes control means (7) comprises, wherein the control means (7) are designed to set a target output voltage of the DC-DC converter (2) lower than 1.05 times the rest voltage of the low-voltage energy storage (3), so that the energy provided by the DC-DC converter (2) as low-voltage DC voltage is not used for charging the low-voltage energy storage device (3) is used. heating system Claim 1 , characterized in that the heating system (20) also comprises a rectifier (5) for converting an alternating voltage into the high-voltage direct voltage. Heating system according to one of the preceding claims, characterized in that the heating system (20) further comprises a high-voltage energy storage device (4) coupled to the DC-DC converter (2) for supplying energy to the heating element (1) for providing the high-voltage DC voltage. heating system Claim 3 , characterized in that the heating system (20) also comprises further control means (8) for controlling the high-voltage energy storage (4), and that the further control means (8) are designed to manage the amount of energy stored in the high-voltage energy storage (4). Supply of the heating element (1) must be taken into account. Vehicle with a high-voltage network (11), a low-voltage network (12), an electric motor (9) for driving the vehicle (10) and a heating system (20) according to one of Claims 1 - 4 , wherein the DC-DC converter (2) of the heating system (20) is coupled to the high-voltage network (11) and the low-voltage network (12) of the vehicle (10), and wherein the heating element (1) of the heating system (20) is connected to the low-voltage network (12) of the vehicle (10) is coupled.

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